Omnidirectional single-input single-output multiband/broadband antennas

What is claimed is: 1. An omnidirectional broadband antenna comprising: a radiator element having a single piece construction including a cone shape defined by multiple petals separated from each other by a gap or spaced distance therebetween and integrally joined to each other at about a center of the radiator element, each of the multiple petals having a stepped configuration; a ground element; and multiple shorting legs extended from the ground element for electrically coupling to and mechanically supporting the multiple petals. 2. The omnidirectional broadband antenna of claim 1 , wherein the ground element includes one or more extended ground studs integrally formed from and extending above the ground element. 3. The omnidirectional broadband antenna of claim 1 , wherein the multiple petals are integrally formed from a same single sheet of material such that the multiple petals are integrally connected to each other at about the center of the radiator element without having to separately weld or join the multiple petals to each other. 4. The omnidirectional broadband antenna of claim 1 , wherein each of the multiple petals has the stepped configuration for electrically lengthening the radiator element. 5. The omnidirectional broadband antenna of claim 1 , wherein each of the multiple petals comprises one or more steps configured for electrically lengthening the radiator element and gradually changing impedance to broaden bandwidth. 6. The omnidirectional broadband antenna of claim 1 , wherein the single piece construction is a central symmetrical structure configured for improving omnidirectional radiation patterns of the radiator element and defined by the multiple petals and the gaps or spaced distances between the multiple petals. 7. The omnidirectional broadband antenna of claim 1 , wherein the number of the multiple shorting legs is the same as the number of multiple petals, and wherein each of the multiple shorting legs is configured to electrically couple to and mechanically support a corresponding one of the multiple petals. 8. The omnidirectional broadband antenna of claim 1 , further comprising multiple holders configured to couple with the multiple shorting legs to further secure the radiator element in place. 9. The omnidirectional broadband antenna of claim 1 , wherein the ground element includes one or more ground flaps to reduce inductance and improve matching of high band that are integrally formed from the ground element such that the ground flaps extend from the ground element at an angle relative to the ground element thereby leaving corresponding openings in the ground element. 10. The omnidirectional broadband antenna of claim 1 , wherein: the multiple petals includes three petals that are separated from each other by a gap or spaced distance therebetween and that are integrally joined to each other at about the center of the radiator element to thereby define the cone shape of the radiator element; and the omnidirectional broadband antenna is operable with a passive intermodulation (IM3) less than −150 decibels relative to carrier (dBc) from about 698 megahertz to about 2700 megahertz. 11. A method of constructing a radiator element for an omnidirectional broadband antenna, the method comprising: stamping a single piece sheet of metal into multiple petals that are separated from each other by a gap or spaced distance therebetween and that are integrally joined to each other at about a center of the stamped single piece sheet of metal; forming each of the multiple petals so as to form a central symmetrical cone shape defined by the multiple petals and the gaps or spaced distances between the multiple petals and such that each of the multiple petals has a stepped configuration; and mechanically supporting the multiple petals using multiple shorting legs extended from a ground element of the omnidirectional broadband antenna. 12. The method of claim 11 , wherein forming each of the multiple petals comprises bending the multiple petals such that each of the multiple petals has the stepped configuration for electrically lengthening the radiator element. 13. The method of claim 11 , wherein forming each of the multiple petals comprises bending the multiple petals such that each of the multiple petals includes one or more steps configured for electrically lengthening the radiator element and gradually changing impedance to broaden bandwidth. 14. The method of claim 11 , wherein the multiple petals are integrally connected to each other at a center of the radiator element and remain integrally connected to each other during and after the stamping and forming without having to weld or join the multiple petals to each other. 15. An omnidirectional broadband single-input single-output multiband antenna comprising: a radiator element having a single piece construction including a cone shape defined by multiple petals that are separated from each other by a gap or spaced distance therebetween and that are integrally connected to each other at a center of the radiator element, each of the multiple petals having a stepped configuration for electrically lengthening the radiator element; a ground element to which the radiator element is shorted; and multiple shorting legs extended from the ground element for electrically coupling to and mechanically supporting the multiple petals. 16. The omnidirectional broadband single-input single-output multiband antenna of claim 15 , wherein: each of the multiple petals comprises one or more steps configured for electrically lengthening the radiator element and gradually changing impedance to broaden bandwidth; and/or the single piece construction is a central symmetrical structure configured for improving omnidirectional radiation patterns of the radiator element. 17. The omnidirectional broadband single-input single-output multiband antenna of claim 15 , wherein the ground element includes one or more ground flaps to reduce inductance and improve matching of high band that are integrally formed from the ground element such that the ground flaps extend from the ground element at an angle relative to the ground element thereby leaving corresponding openings in the ground element.